Adolfo Ruiz Cortines Dam: Difference between revisions
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The mean inflows accumulation to the reservoir over one agricultural year is 1,034 million m<sup>3</sup>. The mean annual agricultural releases are 832 million m<sup>3</sup>. This number does not account for releases for municipal use (around 20 million m<sup>3</sup>), reservoir spills and evaporation losses. semesters. The first semester corresponds to the accumulation of inflows between October and March. This accumulation is important because it determines whether agricultural production occurs in the SS season. According to the data, 30% of the annual accumulations occur in this semester. The second semester corresponds to the period April-October and is the most critical to replenish the reservoir. The data shows that 70% of the inflows occur in this period. <ref name="Irrigation Risk">{{Cite web|url=http://ageconsearch.umn.edu/bitstream/123456789/16404/1/sp05le05.pdf|title=Managing Irrigation Risk with Inflow-Based Derivatives: The Case of Rio Mayo|accessyear=2008|accessmonthday=February 23|publisher=University of Kentucky|year=2005|author=Akssell J. Leiva & Jerry R. Skees|format=pdf|language=English}}</ref> |
The mean inflows accumulation to the reservoir over one agricultural year is 1,034 million m<sup>3</sup>. The mean annual agricultural releases are 832 million m<sup>3</sup>. This number does not account for releases for municipal use (around 20 million m<sup>3</sup>), reservoir spills and evaporation losses. semesters. The first semester corresponds to the accumulation of inflows between October and March. This accumulation is important because it determines whether agricultural production occurs in the SS season. According to the data, 30% of the annual accumulations occur in this semester. The second semester corresponds to the period April-October and is the most critical to replenish the reservoir. The data shows that 70% of the inflows occur in this period. <ref name="Irrigation Risk">{{Cite web|url=http://ageconsearch.umn.edu/bitstream/123456789/16404/1/sp05le05.pdf|title=Managing Irrigation Risk with Inflow-Based Derivatives: The Case of Rio Mayo|accessyear=2008|accessmonthday=February 23|publisher=University of Kentucky|year=2005|author=Akssell J. Leiva & Jerry R. Skees|format=pdf|language=English}}</ref> |
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| ⚫ | As a consequence of droughts that occured |
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==History== |
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In 1985 the dam overflowed reservoir forcing the evacuation of 20,000 people. Water then flowed towards the Pacific coast cut off the international highway and isolated several small towns. The highway was cut south of Ciudad Obregon, 240 miles from the California border. Troops were deployed to help the evacuees, who left their homes after the Mocuzari Dam overflowed. <ref name="reutersflood">{{Cite web|url=http://query.nytimes.com/gst/fullpage.html?res=9502EFDA1E38F932A35752C0A963948260|title= 20,000 Evacuated in Mexico|accessyear=2008|accessmonthday=February 24|publisher=REUTERS |year=1985|language=English}}</ref> |
In 1985 the dam overflowed reservoir forcing the evacuation of 20,000 people. Water then flowed towards the Pacific coast cut off the international highway and isolated several small towns. The highway was cut south of Ciudad Obregon, 240 miles from the California border. Troops were deployed to help the evacuees, who left their homes after the Mocuzari Dam overflowed. <ref name="reutersflood">{{Cite web|url=http://query.nytimes.com/gst/fullpage.html?res=9502EFDA1E38F932A35752C0A963948260|title= 20,000 Evacuated in Mexico|accessyear=2008|accessmonthday=February 24|publisher=REUTERS |year=1985|language=English}}</ref> |
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| ⚫ | As a consequence of droughts that occured the Adolfo Ruiz Cortinez dam on the Mayo River in Sonora had been operating erratically during 2004, which made it impossible to deliver the surface water volumes pledged to Irrigation District 038 in Río Mayo, Sonora, at the start of each agricultural cycle, and caused an overexploitation of groundwater. In order to solve this problem, the State Water Commission of Sonora asked IMTA to determine optimal policies of joint dam-aquifer operation. To do so, methodologies based on dynamic programming and genetic algorithms were used. As a result, an operation policy was recommended that considers an extraction volume from the dam dependent of the storage level at the beginning of the agricultural cycle. Specifically, a minimum extraction volume of 400 hm3 and a maximum extraction volume of 1,100 hm3 were determined. This policy allows to eliminate the deficit in the surface water volumes pledged to the irrigation district and reduce extractions from the Valle del Mayo aquifer. <ref name="mexhydrology">{{Cite web|url=http://www.imta.gob.mx/english/informe-anual/inf-2004/hydrology.pdf|title=Hyrological technology|accessyear=2008|accessmonthday=February 24|publisher=Mexican Institute of Water Technology|year=2004|language=English}}</ref> |
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==Source 7== |
==Source 7== |
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Revision as of 22:29, 22 March 2008
The main source of water supply for the irrigation district is the watershed of the Mayo River (hence the name Rio Mayo), which covers an approximate area of 11,000 km2. The river extends for approximately 350 km and averages 1000 million m3 in streamflows. The hydraulic work used to secure the flows from the river is the ARC reservoir, also known as Mocuzari. The ARC reservoir was built in 1955 and its infrastructure consists of an earth- filled structure 81 m high above the river bed, 775 m long, and 10 m wide at the crest, and 440 m wide at the base. After an expansion project in 1968, the storage capacity increased from 1,100 million m3 to 1,300 million m3. The silting that occurs through the years has reduced the capacity. Of the 51 reservoirs in Mexico, the Adolfo Ruiz Cortines ranks 25th in size. The largest system is over 10,000 million m3 and the smallest is around 270 million m3[citation needed]
The mean inflows accumulation to the reservoir over one agricultural year is 1,034 million m3. The mean annual agricultural releases are 832 million m3. This number does not account for releases for municipal use (around 20 million m3), reservoir spills and evaporation losses. semesters. The first semester corresponds to the accumulation of inflows between October and March. This accumulation is important because it determines whether agricultural production occurs in the SS season. According to the data, 30% of the annual accumulations occur in this semester. The second semester corresponds to the period April-October and is the most critical to replenish the reservoir. The data shows that 70% of the inflows occur in this period. [1]
History
In 1985 the dam overflowed reservoir forcing the evacuation of 20,000 people. Water then flowed towards the Pacific coast cut off the international highway and isolated several small towns. The highway was cut south of Ciudad Obregon, 240 miles from the California border. Troops were deployed to help the evacuees, who left their homes after the Mocuzari Dam overflowed. [2]
As a consequence of droughts that occured the Adolfo Ruiz Cortinez dam on the Mayo River in Sonora had been operating erratically during 2004, which made it impossible to deliver the surface water volumes pledged to Irrigation District 038 in Río Mayo, Sonora, at the start of each agricultural cycle, and caused an overexploitation of groundwater. In order to solve this problem, the State Water Commission of Sonora asked IMTA to determine optimal policies of joint dam-aquifer operation. To do so, methodologies based on dynamic programming and genetic algorithms were used. As a result, an operation policy was recommended that considers an extraction volume from the dam dependent of the storage level at the beginning of the agricultural cycle. Specifically, a minimum extraction volume of 400 hm3 and a maximum extraction volume of 1,100 hm3 were determined. This policy allows to eliminate the deficit in the surface water volumes pledged to the irrigation district and reduce extractions from the Valle del Mayo aquifer. [3]
Source 7
Source 8
- Map [1]
References
- ^ Akssell J. Leiva & Jerry R. Skees (2005). "Managing Irrigation Risk with Inflow-Based Derivatives: The Case of Rio Mayo" (pdf). University of Kentucky.
{{cite web}}: Unknown parameter|accessmonthday=ignored (help); Unknown parameter|accessyear=ignored (|access-date=suggested) (help) - ^ "20,000 Evacuated in Mexico". REUTERS. 1985.
{{cite web}}: Unknown parameter|accessmonthday=ignored (help); Unknown parameter|accessyear=ignored (|access-date=suggested) (help) - ^ "Hyrological technology" (PDF). Mexican Institute of Water Technology. 2004.
{{cite web}}: Unknown parameter|accessmonthday=ignored (help); Unknown parameter|accessyear=ignored (|access-date=suggested) (help) - ^ "Managing Irrigation Risk with Inflow-Based Derivatives: The Case of Rio Mayo" (PDF). Akssell J. Leiva & Jerry R. Skees. 2005.
{{cite web}}: Unknown parameter|accessmonthday=ignored (help); Unknown parameter|accessyear=ignored (|access-date=suggested) (help) - ^ Dr. Jerry R. Skees and Akssell José Leiva (2005). "ANALYSIS OF RISK INSTRUMENTS IN AN IRRIGATION SUB-SECTOR IN MEXICO" (word document).
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